CN116675056A - Double-end winding rubberizing paper blanking system with variable center distance - Google Patents

Abstract

The invention provides a center distance variable double-end winding rubberizing paper blanking system which comprises a fiber guiding mechanism, an optical fiber traction mechanism, a double-end winding mechanism, a rubberizing paper flanging mechanism, a rubberizing paper clamping mechanism and a position adjusting mechanism, wherein the double-end winding mechanism comprises a first winding fiber winding roller, a second winding fiber winding roller and a first driving piece, and the position adjusting mechanism comprises an X/Y/Z axis moving assembly and an R axis rotating assembly; the double-end winding mechanism is arranged corresponding to the gummed paper station, the gummed paper folding mechanism is arranged corresponding to the gummed paper station, and the optical fiber traction mechanism can move back and forth along the X-axis direction. The double-head fiber winding mechanism is designed to adjust the center distance of the double rings of the fiber winding, so that the requirement of diversification of the center distance of products can be met, and meanwhile, the double-head fiber winding, rubberizing paper and blanking procedures are fully automatically operated, so that manual duty is not required, and the labor cost is reduced.

Description

Double-end winding rubberizing paper blanking system with variable center distance

Technical Field

The invention belongs to the technical field of optical fiber processing equipment, and particularly relates to a double-end winding rubberizing paper blanking system with a variable center distance.

Background

In the automatic winding and blanking process of products such as tail fibers, connecting wires, collimators, amplifiers and the like in the optical communication industry, the length of the optical fiber is generally required to be manufactured into different sizes with the length of 0.8-5 meters, the optical fiber is wound into a roll (ring) shape with the outer diameter of about 65-80mm, two adhesive tapes are respectively used for binding at the radial symmetrical positions of the optical fiber roll, and the two adhesive tapes are arranged in order to avoid loosening of the coiled optical fiber, and meanwhile, the specification and model contents of the optical fiber roll are displayed through the adhesive tapes.

For the application scenes of optical fiber transmission devices, beam expansion optical fiber devices, optical fiber gratings and the like which need double-end winding, the double-loop center distance of the existing optical fiber double-end winding device is generally fixed, and the requirements of different application scenes cannot be met; meanwhile, the procedures of pasting the adhesive tape on the coiled optical fiber roll and taking the optical fiber roll are generally realized by manual operation, and the processing mode of pasting the adhesive tape and taking the optical fiber roll manually causes lower production efficiency, higher labor cost and relatively poorer pasting consistency.

Disclosure of Invention

The invention aims to provide a double-end winding rubberizing paper blanking system with a variable center distance, which at least can solve part of defects in the prior art.

In order to achieve the above purpose, the invention adopts the following technical scheme:

the double-end winding and rubberizing paper blanking system with the variable center distance comprises a fiber guiding mechanism, an optical fiber traction mechanism, a double-end winding mechanism, a rubberizing paper flanging mechanism, a rubberizing paper clamping mechanism and a position adjusting mechanism, wherein the double-end winding mechanism comprises a first winding roller, a second winding roller and a first driving piece for driving the first winding roller and the second winding roller to relatively displace, and the position adjusting mechanism comprises an X/Y/Z shaft moving assembly for adjusting the rubberizing paper clamping mechanism to move along X-axis, Y-axis and Z-axis directions and an R-axis rotating assembly for adjusting the rotating angle of the rubberizing paper clamping mechanism; the double-end winding mechanism is arranged corresponding to the gummed paper station, the gummed paper folding mechanism is arranged corresponding to the gummed paper station, and the optical fiber traction mechanism can move back and forth along the X-axis direction.

Further, the double-end fiber winding mechanism further comprises a buffer assembly arranged between the first fiber winding roller and the second fiber winding roller; the buffer assembly comprises a first roller and a second roller which are respectively positioned above and below the optical fiber between the first winding roller and the second winding roller, and a second driving piece and a third driving piece which respectively drive the first roller and the second roller to move up and down, wherein one first roller is arranged, two second rollers are arranged, and the vertical projection of the first roller is positioned between the two second rollers.

Further, the fiber guiding mechanism comprises a fiber placing barrel, a fiber disc, a fiber guiding roller and a length counting assembly, wherein the fiber disc is arranged in the fiber placing barrel, the fiber guiding roller is positioned in front of the length counting assembly, and the length counting assembly is positioned in the movable range of the fiber traction mechanism.

Further, the optical fiber traction mechanism comprises an optical fiber clamping traction assembly and an optical fiber shearing assembly, wherein the optical fiber clamping traction assembly is used for clamping an optical fiber from the optical fiber guiding mechanism and guiding the optical fiber to the double-end fiber winding mechanism, and the optical fiber shearing assembly is used for shearing the optical fiber pulled to the double-end fiber winding mechanism according to a set length.

Further, the gummed paper flanging mechanism comprises a gummed paper installation assembly, a gummed paper traction assembly, a gummed paper picking assembly, a gummed paper double-end flanging assembly and a fourth driving piece for driving the gummed paper picking assembly to move between the gummed paper traction assembly and the gummed paper double-end flanging assembly; the gummed paper traction assembly comprises a traction piece and a shearing piece, wherein the traction piece is used for clamping gummed paper from the gummed paper installation assembly and dragging the gummed paper to the gummed paper pickup assembly, and the shearing piece is used for shearing the gummed paper pulled to the gummed paper pickup assembly according to a set length.

Further, the gummed paper picking assembly comprises gummed paper picking fingers and a telescopic sliding table, the telescopic sliding table is connected to the fourth driving piece, the gummed paper picking fingers are connected to the telescopic sliding table, the gummed paper traction assembly and the gummed paper double-end flanging assembly are located on the same side of the fourth driving piece, and the telescopic sliding table drives the gummed paper picking fingers to be close to or far away from the gummed paper traction assembly/gummed paper double-end flanging assembly.

Further, the gummed paper double-end flanging assembly comprises a pair of flanging parts I, a pair of flanging parts II and gummed paper flanging air cylinders, wherein the flanging parts I and II are symmetrically arranged in a common symmetry axis, gummed paper grooves are formed between the flanging parts I and II on the same side, the distance between the bottoms of the gummed paper grooves on two sides is smaller than the length of gummed paper to be flanged, and the gummed paper flanging air cylinders drive the flanging parts I and II to relatively displace so as to open and close the gummed paper grooves.

Further, the rubberizing paper clamping mechanism comprises two groups of bending assemblies, a positioning guide column, a fifth driving piece and a rubberizing power assembly, wherein vacuum adsorption holes for adsorbing the gummed paper are formed in the ends of the bending assemblies and the positioning guide column, the two groups of bending assemblies are respectively positioned on two sides of the positioning guide column, the fifth driving piece drives the two groups of bending assemblies to move along the positioning guide column so as to downwards press two ends of the gummed paper subjected to vacuum adsorption, and the rubberizing power assembly drives the downwards-pressed gummed paper ends of the two groups of bending assemblies to mutually approach to enable the two ends of the gummed paper to be attached.

Further, the subassembly of bending includes bending pole and gyro wheel, two sets of the bending pole upper end of subassembly of bending passes through connecting rod and location guide post sliding connection, and articulates between bending pole and the connecting rod, press from both sides and paste the hinge point rotation of power component drive two bending poles around its and connecting rod, gyro wheel one end is connected in bending pole lower extreme, and the gyro wheel other end contacts with the location guide post.

Further, the X/Y/Z axis moving assembly comprises an X axis moving module, a Y axis linear module and a Z axis linear module, the R axis rotating assembly comprises a rotating shaft and a sixth driving piece for driving the rotating shaft to rotate, the adhesive paper clamping mechanism is connected to the rotating shaft of the R axis rotating assembly, the R axis rotating assembly is connected to the Y axis linear module, the Y axis linear module is connected to the Z axis linear module, and the Z axis linear module is connected to the X axis moving module in a sliding manner.

Compared with the prior art, the invention has the beneficial effects that:

(1) The double-end winding mechanism is designed in the blanking system of the double-end winding rubberizing paper with the variable center distance for adjusting the double-circle center distance of the winding fiber, so that the requirement of diversification of the center distance of products can be met, and meanwhile, the double-end winding, rubberizing paper and blanking procedures are fully automatically operated, so that manual duty is not required, and the labor cost is reduced.

(2) According to the center-distance-variable double-end winding rubberizing paper blanking system, the gumming paper flanging mechanism is adopted to carry out double-end flanging on gummed paper, so that later tearing is facilitated, meanwhile, the rubberizing paper clamping mechanism is adopted to carry out gumming paper and blanking on wound fiber, and defects such as pull damage and scratch of optical fiber are avoided.

The present invention will be described in further detail with reference to the accompanying drawings.

Drawings

FIG. 1 is a schematic diagram of a system for blanking a double-ended wound fiber rubberized paper with a variable center distance;

FIG. 2 is a schematic illustration of a two-headed glue assembly of the present invention;

FIG. 3 is a schematic view of the working state of the gummed paper double-ended folding assembly of the present invention when the gummed paper groove is closed to finish the gummed paper folding;

FIG. 4 is a schematic diagram of an arrangement of a rubberizing paper mechanism of the invention;

fig. 5 is a schematic view of the A-A direction gummed paper clamping mechanism in fig. 4 in a gummed paper clamping state.

Reference numerals illustrate: 1. fiber releasing barrel; 2. an optical fiber tray; 3. a fiber guiding roller; 4. a length counting assembly; 5. an optical fiber traction mechanism; 6. a first winding reel; 7. a first roller; 8. a second roller; 9. a second winding reel; 10. glue paper; 11. a gummed paper mounting assembly; 12. a gummed paper traction assembly; 13. a gummed paper pick-up assembly; 14. a fourth driving member; 15. double-end edge folding assembly of gummed paper; 16. a rubberizing paper clamping mechanism; 17. an R-axis rotating assembly; 18. an X/Y/Z axis movement assembly; 19. a first flanging part; 20. a gummed paper groove; 21. a second flanging part; 22. positioning a guide column; 23. bending the rod; 24. vacuum adsorption holes; 25. a connecting rod; 26. clamping and pasting a power assembly; 27. and a roller.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, it should be understood that the terms "center," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the present invention and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or by an abutting connection or integrally connected; the specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

The terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first", "a second" may include one or more such features, either explicitly or implicitly; in the description of the present invention, unless otherwise indicated, the meaning of "a plurality" is two or more.

As shown in fig. 1, the present embodiment provides a center-to-center distance variable double-end winding and rubberizing paper blanking system, which comprises a fiber guiding mechanism, an optical fiber traction mechanism 5, a double-end winding mechanism, a rubberizing paper flanging mechanism, a rubberizing paper clamping mechanism 16 and a position adjusting mechanism, wherein the double-end winding mechanism comprises a first winding and coiling wheel 6, a second winding and coiling wheel 9 and a first driving piece for driving the first winding and coiling wheel 6 and the second winding and coiling wheel 9 to relatively displace, and the position adjusting mechanism comprises an X/Y/Z axis moving component 18 for adjusting the rubberizing paper clamping mechanism 16 to move along the X axis, the Y axis and the Z axis directions, and an R axis rotating component 17 for adjusting the rotation angle of the rubberizing paper clamping mechanism 16; the adhesive paper clamping and pasting mechanism 16 is correspondingly provided with an adhesive paper pasting station, an edge folding adhesive paper taking station and a blanking station in the moving range of the X-axis direction, the double-end winding mechanism is correspondingly arranged at the adhesive paper pasting station, the adhesive paper edge folding mechanism is correspondingly arranged at the edge folding adhesive paper taking station, and the optical fiber traction mechanism 5 can move back and forth along the X-axis direction. In this embodiment, the first winding roller 6 is fixed in position, and the first driving member drives the second winding roller 9 to move to adjust the center distances S of the two different coils.

When the optical fiber winding device works, the distance between the first winding roller 6 and the second winding roller 9 is adjusted to a designed double-circle center distance S through the first driving piece, the optical fiber is penetrated according to a fiber penetrating path, the optical fiber is guided to the optical fiber traction mechanism 5 through the fiber guiding mechanism, the optical fiber traction mechanism 5 pulls the optical fiber head to penetrate through the first winding roller 6 to the second winding roller 9, the second winding roller 9 clamps the optical fiber head to rotate and wind, after the optical fiber length reaches a set length, the first winding roller 6 clamps the tail of the optical fiber to cut the optical fiber, the first winding roller 6 rotates and winds, meanwhile, the second winding roller 9 reversely winds the optical fiber on the second winding roller 9, and part of the optical fiber is reversely conveyed to the first winding roller 6, so that a double-end winding structure for winding the optical fiber with the set length to the designed double-circle center distance is realized; in the process of winding the optical fiber, the adhesive tape 10 is fed onto an adhesive tape folding mechanism to carry out double-end folding, an X/Y/Z axis moving assembly 18 firstly drives an adhesive tape clamping mechanism 16 to move to a folded adhesive tape taking station in the X axis direction, then the X/Y/Z axis moving assembly 18 readjusts the positions of the adhesive tape clamping mechanism 16 in the Y axis direction and the Z axis direction, so that the adhesive tape clamping mechanism 16 can pick up the adhesive tape 10 folded on the adhesive tape folding mechanism, then the adhesive tape clamping mechanism 16 moves to a first fiber winding wheel 6 of the adhesive tape clamping station along the X axis direction with the adhesive tape 10 of the double-end folding, the positions of the adhesive tape clamping mechanism 16 in the Y axis direction and the Z axis direction are adjusted through the X/Y/Z axis moving assembly 18, the positions of the optical fiber needing adhesive tape clamping after the optical fiber winding is completed on the first fiber winding wheel 6 of the double-end winding mechanism are adjusted through an R axis rotating assembly 17, the adhesive tape clamping mechanism 16 is positioned on the two ends of the optical fiber winding mechanism 10, and then the optical fiber is folded on the double-end winding wheel 10 of the double-end optical fiber winding mechanism; then the adhesive paper clamping mechanism 16 adopts the same process, and after the adhesive paper 10 with folded edges is picked up on the adhesive paper folding mechanism, the adhesive paper is moved to the second fiber winding roller 9 to be stuck with the adhesive paper 10 with double-end folded edges; after the rubberizing of the second winding roller 9 is finished, the X/Y/Z axis moving assembly 18 drives the rubberizing paper clamping mechanism to retract and take away the optical fiber ring of the rubberizing paper on the second winding roller 9 along the Y axis, meanwhile, the optical fiber ring of the rubberizing paper on the first winding roller 6 is driven by the optical fiber ring on the second winding roller 9 to retract and take away along the Y axis, and finally, the rubberizing paper clamping mechanism 16 moves to a blanking station along the X axis direction for blanking. The double-end winding mechanism is designed in the double-end winding rubberizing paper blanking system with the variable center distance, and the double-circle center distance of the winding is adjusted, so that the requirement of product center distance diversification can be met, and meanwhile, the double-end winding, rubberizing paper and blanking procedures are fully automatically operated, manual duty is not required, and labor cost is reduced.

The implementation mode of refining, the first is around fine reel 6 and the second is around fine reel 9 the same in structure, all includes carousel base, carousel clamp fine subassembly and around fine clamping jaw subassembly, the carousel base is discoid, installs on carousel motor output shaft, the carousel clamp fine subassembly is installed on the carousel base for clip optic fibre head/optic fibre afterbody, around fine clamping jaw subassembly includes a plurality of around fine fingers of follow carousel base circumference equidistant arrangement, at optic fibre winding in-process, optic fibre is around fine clamping jaw subassembly around fine fingers and is around the fine finger and carry out the circle. In order to meet the requirements of different winding diameters, the winding diameter of the fiber winding wheel is optimally designed to be of a variable diameter structure, specifically, a power piece for driving fiber winding fingers to move along the radial direction of the turntable base is arranged on the turntable base, the diameter of the winding is determined by adjusting the radial position of the fiber winding fingers in the fiber winding clamping jaw assembly along the turntable base, namely, the farther the fiber winding fingers are away from the center of the turntable base, the larger the diameter of the winding is, and conversely, the smaller the diameter of the winding is; the diameter of the optical fiber winding is adjusted by changing the position of the finger of the winding fiber, so that the winding products of the blanking are diversified, and different application requirements can be met.

In an optimized embodiment, as shown in fig. 1, the double-end fiber winding mechanism further comprises a buffer assembly arranged between the first fiber winding roller 6 and the second fiber winding roller 9; the buffer assembly comprises a first roller 7 and a second roller 8 which are respectively positioned above and below the optical fiber between a first winding roller 6 and a second winding roller 9, and a second driving piece and a third driving piece which respectively drive the first roller 7 and the second roller 8 to move up and down, wherein one first roller 7 is arranged, two second rollers 8 are arranged, and the vertical projection of the first roller 7 is positioned between the two second rollers 8. Before the first fiber winding reel 6 clamps the tail part of the optical fiber to drive the second fiber winding reel 9 to reversely wind, the second driving piece drives the first roller 7 to descend and press the optical fiber, meanwhile, the third driving piece drives the two second rollers 8 to ascend and prop against the optical fiber, the first roller 7 is positioned below the two second rollers 8, and through the structural design of the buffer component, the first fiber winding reel 6 and the second fiber winding reel 9 synchronously rotate during rotation, so that the optical fiber damage caused by the asynchronous rotation of the first fiber winding reel 6 and the second fiber winding reel 9 is effectively avoided.

In a specific embodiment, as shown in fig. 1, the fiber guiding mechanism includes a fiber releasing barrel 1, a fiber disc 2, a fiber guiding roller 3 and a length counting assembly 4, the fiber disc 2 is arranged in the fiber releasing barrel 1, the fiber is automatically released through the fiber disc 2, the fiber guiding roller 3 is positioned in front of the length counting assembly 4, the fiber guiding roller 3 guides the released fiber movement, and the length counting assembly 4 is positioned in the movable range of the fiber traction mechanism 5; according to the fiber penetrating path, the fiber is manually penetrated, and the fiber sequentially passes through the fiber guiding roller 3 and the length counting assembly 4 to the fiber traction mechanism 5.

Specifically, the optical fiber traction mechanism 5 comprises a fiber clamping traction component and a fiber shearing component, after fiber penetration is completed, the fiber clamping traction component clamps the optical fiber on the fiber guiding mechanism and moves right, at the moment, the length counting component 4 starts to count length, the fiber clamping traction component pulls the optical fiber to pass through the first fiber winding roller 6 and deliver the head of the optical fiber to the second fiber winding roller 9, then the fiber clamping traction component moves left, the second fiber winding roller 9 clamps the fiber to rotate clockwise, after the length counting component 4 counts length to reach a set length, the first fiber winding roller 6 clamps the tail of the optical fiber with the set length, meanwhile, the fiber clamping traction component clamps the optical fiber, and the fiber shearing component stretches out of the closed shearing fiber of the scissors. After the adhesive paper clamping mechanism 16 takes the optical fiber ring of the adhesive paper on the double-end winding mechanism, the optical fiber is pulled to the right by the optical fiber clamping traction component, the process is repeated, and the winding, adhesive paper and blanking processes of the next winding product are started.

For the specific embodiment of automatic blanking of the double-end folding of the gummed paper, as shown in fig. 1, the gummed paper folding mechanism comprises a gummed paper mounting assembly 11, a gummed paper traction assembly 12, a gummed paper picking-up assembly 13, a gummed paper double-end folding assembly 15, and a fourth driving piece 14 for driving the gummed paper picking-up assembly 13 to move between the gummed paper traction assembly 12 and the gummed paper double-end folding assembly 15; the adhesive tape mounting assembly 11 is used for automatically unreeling the adhesive tape 10, the adhesive tape traction assembly 12 comprises a traction piece and a shearing piece, the traction piece is used for clamping the adhesive tape 10 from the adhesive tape mounting assembly 11 and dragging the adhesive tape 10 to the adhesive tape pickup assembly 13, the adhesive tape pickup assembly 13 picks up the adhesive tape 10, and the shearing piece is used for shearing the adhesive tape 10 pulled to the adhesive tape pickup assembly 13 according to a set length.

Specifically, the gummed paper picking assembly 13 comprises a gummed paper picking finger and a telescopic sliding table, the telescopic sliding table is connected to the fourth driving piece 14, the gummed paper picking finger is connected to the telescopic sliding table, the gummed paper traction assembly 12 and the gummed paper double-end flanging assembly 15 are located on the same side of the fourth driving piece 14, and the telescopic sliding table drives the gummed paper picking finger to be close to or far away from the gummed paper traction assembly 12/gummed paper double-end flanging assembly 15. The traction piece is used for clamping the gummed paper 10 on the gummed paper installation component 11 and then downwards moving to the gummed paper pickup component 13, the telescopic sliding table drives the gummed paper pickup fingers to extend out of the gummed paper 10, the traction piece of the gummed paper traction component 12 is restored to the original position to clamp the gummed paper 10, the shearing piece on the gummed paper traction component 12 is used for shearing the gummed paper 10 clamped between the traction piece and the gummed paper pickup fingers 13 according to the design length, the gummed paper part clamped by the gummed paper pickup fingers is the gummed paper 10 to be folded in double-end mode, at the moment, the gummed paper pickup fingers are clamped in the middle of the gummed paper to be folded in double-end mode, two ends of the gummed paper to be folded in double-end mode extend out of the gummed paper to be folded in double-end mode, then the telescopic sliding table drives the gummed paper pickup fingers to retract, the gummed paper pickup component 13 is driven to move to the gummed paper double-end folding component 15, and the telescopic sliding table drives the gummed paper pickup fingers to extend out of the gummed paper pickup fingers, so that the gummed paper to be folded in double-end folding mode on the gummed paper pickup fingers to be folded in double-end mode on the gummed paper double-end folding component 15.

Specifically, as shown in fig. 2 and 3, the double-end edge folding assembly 15 for gummed paper includes a pair of first edge folding portions 19, a pair of second edge folding portions 21, and a gummed paper edge folding cylinder (not shown in the drawings), where the pair of first edge folding portions 19 and the pair of second edge folding portions 21 are symmetrically arranged along a common symmetry axis, and the first edge folding portions 19 and the second edge folding portions 21 on the same side form a gummed paper groove 20, the distance between the bottoms of the gummed paper grooves 20 on two sides is smaller than the length of gummed paper to be folded, and the gummed paper edge folding cylinder drives the first edge folding portions 19 and the second edge folding portions 21 to relatively displace so as to open and close the gummed paper groove 20. When the folding work, the telescopic sliding table of the gummed paper picking assembly 13 drives the gummed paper picking fingers to be close to the gummed paper double-end folding assembly 15, as the distance between the gummed paper grooves 20 on the two sides of the gummed paper double-end folding assembly 15 is smaller than the length of the gummed paper 10 to be folded, when the gummed paper picking fingers clamp the gummed paper 10 to enter the gummed paper double-end folding assembly 15, the two ends of the gummed paper 10 can be folded, when the gummed paper 10 is positioned at the gummed paper groove 20 of the gummed paper double-end folding assembly 15, the bending parts at the two ends of the gummed paper 10 are filled in the gummed paper grooves 20, the gummed paper folding cylinder drives the first 19 and the second 21 to be close to each other, so that the gummed paper grooves 20 are closed, the two ends of the gummed paper 10 are filled in the gummed paper grooves 20 to be folded and attached, the double-end folding of the gummed paper 10 is completed, then the telescopic sliding table is retracted, the gummed paper picking fingers are driven to be far away from the gummed paper 10 after folding and restored to the initial position, and simultaneously, the gummed paper 10 after the folding is picked up by the gummed paper clamping mechanism 16 is picked up, and the gummed paper cylinder drives the first 19 and the second 21 to be far away from the gummed paper part to be restored to form the initial gummed paper groove 20, so that the next folding work is conveniently carried out.

Optimally, a laser marking machine can be arranged between the gummed paper mounting assembly 11 and the gummed paper traction assembly 12, and the two-dimensional code or the characters can be marked on the gummed paper through the laser marking machine, so that the product can be traced.

Specifically, as shown in fig. 4 and fig. 5, the adhesive paper clamping mechanism 16 includes two sets of bending assemblies, a positioning guide post 22, a fifth driving member and an adhesive power assembly 26, the ends of the bending assemblies and the positioning guide post 22 are respectively provided with a vacuum adsorption hole 24 for adsorbing the adhesive paper 10, two sets of bending assemblies are respectively located at two sides of the positioning guide post 22, the fifth driving member drives the two sets of bending assemblies to move along the positioning guide post 22 to press two ends of the adhesive paper 10 with vacuum adsorption, and the adhesive power assembly 26 drives the pressed adhesive paper ends of the two sets of bending assemblies to be close to each other, so that two ends of the adhesive paper 10 are attached. The clamping power assembly 26 may adopt a tension spring, and two ends of the tension spring are respectively connected with the two sets of bending assemblies. When the device works, the bending assembly and the vacuum adsorption holes 24 on the positioning guide column 22 adsorb the double-headed folded adhesive tape 10 on the double-headed folded adhesive tape assembly 15, then the X/Y/Z axis moving assembly 18 drives the adhesive tape clamping mechanism 16 to move to the adhesive tape station, the positions of the adhesive tape 10 are adjusted, the adhesive tape clamping mechanism 16 is moved to the position of the optical fiber ring on the double-headed winding mechanism, the direction of the adhesive tape clamping mechanism 16 is adjusted through the R axis rotating assembly 17, the middle part of the adhesive tape 10 is attached to the surface of the optical fiber ring, the two ends of the adhesive tape 10 are respectively positioned on the two sides of the optical fiber ring, the two groups of bending assemblies are respectively positioned on the upper surfaces of the two ends of the adhesive tape 10, the adhesive tape 10 is simultaneously pressed by the fifth driving piece, the two groups of bending assemblies take the two sides of the optical fiber ring as folded edges, and the lower ends of the adhesive tape 10 are simultaneously driven to be close to each other by the adhesive tape clamping power assembly 26 in the bending process of the adhesive tape 10, so that the two ends of the adhesive tape 10 are attached to each other, and the optical fiber ring is wrapped, and the adhesive tape adhering process of the optical fiber ring is completed; in the process, the positioning guide column 22 plays a role in positioning and guiding, the positioning guide column 22 is used for positioning and aligning the surface of the optical fiber ring to be rubberized paper, and the lower end of the positioning guide column 22 presses the middle part of the gummed paper 10, so that the middle part of the gummed paper 10 is attached to the surface of the optical fiber ring; meanwhile, the fifth driving piece drives the two groups of bending assemblies to move along the positioning guide column 22, the positioning guide column 22 plays a guiding role in the process of pressing the gummed paper on the bending assemblies, and the clamping power assembly 26 can enable the two groups of bending assemblies to be mutually symmetrically close to each other by taking the axis of the positioning guide column 22 as a symmetry axis so as to attach two ends of the gummed paper 10, so that the stability of the gummed paper attaching quality is ensured. After that, the fiber winding fingers of the double-end fiber winding mechanism shrink, the fiber winding head is loosened by the fiber clamping assembly of the turntable, the adhesive tape clamping mechanism 16 clamps the optical fiber ring of the adhesive tape, the X/Y/Z axis moving assembly 18 drives the adhesive tape clamping mechanism 16 to retract along the Y axis, and the adhesive tape clamping mechanism 16 takes the optical fiber ring of the adhesive tape from the double-end fiber winding mechanism.

Optionally, the bending assembly includes bending rod 23 and gyro wheel 27, two sets of bending rod 23 upper end of the bending assembly passes through connecting rod 25 and location guide post 22 sliding connection, and articulates between bending rod 23 and the connecting rod 25, press from both sides and paste power pack 26 drive two bending rods 23 around its hinge point rotation with connecting rod 25, gyro wheel 27 one end is connected in bending rod 23 lower extreme, and the gyro wheel 27 other end contacts with location guide post 22. The two bending rods 23 are connected through the connecting rod 25, the movable end of the fifth driving piece is connected with the connecting rod 25, the connecting rod 25 is driven to move along the axis of the positioning guide post, the two bending rods 23 can be driven to synchronously move to press two ends of the adhesive tape 10, the adhesive tape 10 is pressed down by the bending rods 23, in the bending process of the adhesive tape 10, the clamping power assembly 26 drives the two bending rods 23 to rotate inwards around the hinging point of the clamping power assembly and the connecting rod 25, the rollers 27 on two sides are close to each other, the lower ends of the two bending rods 23 (namely, the ends of the bending rods, which are contacted with the adhesive tape) are close to each other, so that the adhesive tape is pasted on the optical fiber ring and then is pasted together.

Specifically, the X/Y/Z axis moving assembly 18 includes an X axis moving module, a Y axis linear module, and a Z axis linear module, the R axis rotating assembly 17 includes a rotating shaft and a sixth driving member that drives the rotating shaft to rotate, the adhesive-clip paper mechanism 16 is connected to the rotating shaft of the R axis rotating assembly 17, the rotating shaft is perpendicular to the plane where the optical fiber ring is located, the angle of the adhesive-clip paper on the adhesive-clip mechanism 16 is adjusted by rotating the rotating shaft, the R axis rotating assembly 17 is connected to the Y axis linear module, the R axis rotating assembly 17 is adjusted by the Y axis linear module and drives the position of the adhesive-clip paper mechanism 16 in the Y axis direction, the Y axis linear module is connected to the Z axis linear module, and the position of the Y axis linear module in the Z axis direction is adjusted by the Z axis linear module, thereby driving the position of the adhesive-clip paper mechanism 16 in the Z axis direction, and the Z axis linear module is slidingly connected to the X axis moving module. Wherein, X axle removes module, Y axle straight line module and Z axle straight line module and all are prior art, and its specific structure and theory of operation are here not repeated.

The foregoing examples are merely illustrative of the present invention and are not intended to limit the scope of the present invention, and all designs that are the same or similar to the present invention are within the scope of the present invention.

Claims (10)

1. The utility model provides a variable double-end around fine rubberizing paper unloading system of centre-to-centre spacing which characterized in that: the double-end winding mechanism comprises a first winding roller, a second winding roller and a first driving piece for driving the first winding roller and the second winding roller to relatively displace, and the position adjusting mechanism comprises an X/Y/Z axis moving component for adjusting the movement of the adhesive tape clamping mechanism along X axis, Y axis and Z axis directions and an R axis rotating component for adjusting the rotation angle of the adhesive tape clamping mechanism; the double-end winding mechanism is arranged corresponding to the gummed paper station, the gummed paper folding mechanism is arranged corresponding to the gummed paper station, and the optical fiber traction mechanism can move back and forth along the X-axis direction.

2. The center-to-center variable double-ended wound-fiber rubberized paper blanking system of claim 1, wherein: the double-end fiber winding mechanism further comprises a buffer assembly arranged between the first fiber winding roller and the second fiber winding roller; the buffer assembly comprises a first roller and a second roller which are respectively positioned above and below the optical fiber between the first winding roller and the second winding roller, and a second driving piece and a third driving piece which respectively drive the first roller and the second roller to move up and down, wherein one first roller is arranged, two second rollers are arranged, and the vertical projection of the first roller is positioned between the two second rollers.

3. The center-to-center variable double-ended wound-fiber rubberized paper blanking system of claim 1, wherein: the optical fiber guiding mechanism comprises an optical fiber placing barrel, an optical fiber disc, an optical fiber guiding roller and a length counting assembly, wherein the optical fiber disc is arranged in the optical fiber placing barrel, the optical fiber guiding roller is positioned in front of the length counting assembly, and the length counting assembly is positioned in the movable range of the optical fiber traction mechanism.

4. The center-to-center variable double-ended wound-fiber rubberized paper blanking system of claim 1, wherein: the optical fiber traction mechanism comprises an optical fiber clamping traction assembly and an optical fiber shearing assembly, wherein the optical fiber clamping traction assembly is used for clamping optical fibers from the optical fiber guiding mechanism and guiding the optical fibers to the double-end optical fiber winding mechanism, and the optical fiber shearing assembly is used for shearing the optical fibers pulled to the double-end optical fiber winding mechanism according to a set length.

5. The center-to-center variable double-ended wound-fiber rubberized paper blanking system of claim 1, wherein: the gummed paper flanging mechanism comprises a gummed paper installation assembly, a gummed paper traction assembly, a gummed paper picking assembly, a gummed paper double-end flanging assembly and a fourth driving piece for driving the gummed paper picking assembly to move between the gummed paper traction assembly and the gummed paper double-end flanging assembly; the gummed paper traction assembly comprises a traction piece and a shearing piece, wherein the traction piece is used for clamping gummed paper from the gummed paper installation assembly and dragging the gummed paper to the gummed paper pickup assembly, and the shearing piece is used for shearing the gummed paper pulled to the gummed paper pickup assembly according to a set length.

6. The center-to-center variable double-ended wound-fiber rubberized paper blanking system of claim 5, wherein: the gummed paper picking assembly comprises gummed paper picking fingers and a telescopic sliding table, the telescopic sliding table is connected to the fourth driving piece, the gummed paper picking fingers are connected to the telescopic sliding table, the gummed paper traction assembly and the gummed paper double-end flanging assembly are located on the same side of the fourth driving piece, and the telescopic sliding table drives the gummed paper picking fingers to be close to or far away from the gummed paper traction assembly/gummed paper double-end flanging assembly.

7. The center-to-center variable double-ended wound-fiber rubberized paper blanking system of claim 5, wherein: the double-end adhesive tape folding assembly comprises a pair of first folding parts, a pair of second folding parts and an adhesive tape folding cylinder, wherein the pair of first folding parts and the pair of second folding parts are symmetrically arranged along a common symmetry axis, adhesive tape grooves are formed between the first folding parts and the second folding parts on the same side, the distance between the bottoms of the adhesive tape grooves on two sides is smaller than the length of adhesive tape to be folded, and the adhesive tape folding cylinder drives the first folding parts and the second folding parts to relatively displace so as to open and close the adhesive tape grooves.

8. The center-to-center variable double-ended wound-fiber rubberized paper blanking system of claim 1, wherein: the adhesive paper clamping mechanism comprises two groups of bending assemblies, a positioning guide column, a fifth driving piece and an adhesive paper clamping power assembly, wherein vacuum adsorption holes for adsorbing adhesive paper are formed in the ends of the bending assemblies and the positioning guide column, the two groups of bending assemblies are respectively located on two sides of the positioning guide column, the fifth driving piece drives the two groups of bending assemblies to move along the positioning guide column so as to downwards press the two ends of the adhesive paper subjected to vacuum adsorption, and the adhesive paper clamping power assembly drives the two groups of pressing adhesive paper ends of the bending assemblies to be close to each other so that the two ends of the adhesive paper are attached.

9. The center-to-center variable double-ended wound-fiber rubberized paper blanking system of claim 8, wherein: the bending assembly comprises bending rods and rollers, the upper ends of the bending rods of the bending assembly are connected with the positioning guide columns in a sliding mode through connecting rods, the bending rods are hinged to the connecting rods, the clamping power assembly drives the two bending rods to rotate around the hinge points of the clamping power assembly and the connecting rods, one ends of the rollers are connected to the lower ends of the bending rods, and the other ends of the rollers are in contact with the positioning guide columns.

10. The center-to-center variable double-ended wound-fiber rubberized paper blanking system of claim 1, wherein: the X/Y/Z axis moving assembly comprises an X axis moving module, a Y axis linear module and a Z axis linear module, the R axis rotating assembly comprises a rotating shaft and a sixth driving piece for driving the rotating shaft to rotate, the adhesive paper clamping mechanism is connected to the rotating shaft of the R axis rotating assembly, the R axis rotating assembly is connected to the Y axis linear module, the Y axis linear module is connected to the Z axis linear module, and the Z axis linear module is connected to the X axis moving module in a sliding manner.